4.55E1Parts per MillionThe number of spectral counts (SC) is approximately proportional to the product of the protein concentration and molecular weight (MW), therefore we estimate the fraction of total molecules in parts per million (PPM) by $$PPM_i={SC_i\/MW_i}/∑↙{j=1}↖n {SC_j\/MW_j}$$ where MWi is the molecular weight and SCi is the number of spectral counts for protein i and the summation in the denominator is over all the proteins identified in the experiment for a given tissue and condition.

1.15E1Parts per MillionThe number of spectral counts (SC) is approximately proportional to the product of the protein concentration and molecular weight (MW), therefore we estimate the fraction of total molecules in parts per million (PPM) by $$PPM_i={SC_i\/MW_i}/∑↙{j=1}↖n {SC_j\/MW_j}$$ where MWi is the molecular weight and SCi is the number of spectral counts for protein i and the summation in the denominator is over all the proteins identified in the experiment for a given tissue and condition.

9.28E0Parts per MillionThe number of spectral counts (SC) is approximately proportional to the product of the protein concentration and molecular weight (MW), therefore we estimate the fraction of total molecules in parts per million (PPM) by $$PPM_i={SC_i\/MW_i}/∑↙{j=1}↖n {SC_j\/MW_j}$$ where MWi is the molecular weight and SCi is the number of spectral counts for protein i and the summation in the denominator is over all the proteins identified in the experiment for a given tissue and condition.

7.68E0Parts per MillionThe number of spectral counts (SC) is approximately proportional to the product of the protein concentration and molecular weight (MW), therefore we estimate the fraction of total molecules in parts per million (PPM) by $$PPM_i={SC_i\/MW_i}/∑↙{j=1}↖n {SC_j\/MW_j}$$ where MWi is the molecular weight and SCi is the number of spectral counts for protein i and the summation in the denominator is over all the proteins identified in the experiment for a given tissue and condition.

6.9E0Parts per MillionThe number of spectral counts (SC) is approximately proportional to the product of the protein concentration and molecular weight (MW), therefore we estimate the fraction of total molecules in parts per million (PPM) by $$PPM_i={SC_i\/MW_i}/∑↙{j=1}↖n {SC_j\/MW_j}$$ where MWi is the molecular weight and SCi is the number of spectral counts for protein i and the summation in the denominator is over all the proteins identified in the experiment for a given tissue and condition.

6.3E0Parts per MillionThe number of spectral counts (SC) is approximately proportional to the product of the protein concentration and molecular weight (MW), therefore we estimate the fraction of total molecules in parts per million (PPM) by $$PPM_i={SC_i\/MW_i}/∑↙{j=1}↖n {SC_j\/MW_j}$$ where MWi is the molecular weight and SCi is the number of spectral counts for protein i and the summation in the denominator is over all the proteins identified in the experiment for a given tissue and condition.

6.06E0Parts per MillionThe number of spectral counts (SC) is approximately proportional to the product of the protein concentration and molecular weight (MW), therefore we estimate the fraction of total molecules in parts per million (PPM) by $$PPM_i={SC_i\/MW_i}/∑↙{j=1}↖n {SC_j\/MW_j}$$ where MWi is the molecular weight and SCi is the number of spectral counts for protein i and the summation in the denominator is over all the proteins identified in the experiment for a given tissue and condition.

5.31E0Parts per MillionThe number of spectral counts (SC) is approximately proportional to the product of the protein concentration and molecular weight (MW), therefore we estimate the fraction of total molecules in parts per million (PPM) by $$PPM_i={SC_i\/MW_i}/∑↙{j=1}↖n {SC_j\/MW_j}$$ where MWi is the molecular weight and SCi is the number of spectral counts for protein i and the summation in the denominator is over all the proteins identified in the experiment for a given tissue and condition.

5.3E0Parts per MillionThe number of spectral counts (SC) is approximately proportional to the product of the protein concentration and molecular weight (MW), therefore we estimate the fraction of total molecules in parts per million (PPM) by $$PPM_i={SC_i\/MW_i}/∑↙{j=1}↖n {SC_j\/MW_j}$$ where MWi is the molecular weight and SCi is the number of spectral counts for protein i and the summation in the denominator is over all the proteins identified in the experiment for a given tissue and condition.

5.01E0Parts per MillionThe number of spectral counts (SC) is approximately proportional to the product of the protein concentration and molecular weight (MW), therefore we estimate the fraction of total molecules in parts per million (PPM) by $$PPM_i={SC_i\/MW_i}/∑↙{j=1}↖n {SC_j\/MW_j}$$ where MWi is the molecular weight and SCi is the number of spectral counts for protein i and the summation in the denominator is over all the proteins identified in the experiment for a given tissue and condition.

4.78E0Parts per MillionThe number of spectral counts (SC) is approximately proportional to the product of the protein concentration and molecular weight (MW), therefore we estimate the fraction of total molecules in parts per million (PPM) by $$PPM_i={SC_i\/MW_i}/∑↙{j=1}↖n {SC_j\/MW_j}$$ where MWi is the molecular weight and SCi is the number of spectral counts for protein i and the summation in the denominator is over all the proteins identified in the experiment for a given tissue and condition.

4.66E0Parts per MillionThe number of spectral counts (SC) is approximately proportional to the product of the protein concentration and molecular weight (MW), therefore we estimate the fraction of total molecules in parts per million (PPM) by $$PPM_i={SC_i\/MW_i}/∑↙{j=1}↖n {SC_j\/MW_j}$$ where MWi is the molecular weight and SCi is the number of spectral counts for protein i and the summation in the denominator is over all the proteins identified in the experiment for a given tissue and condition.

4.58E0Parts per MillionThe number of spectral counts (SC) is approximately proportional to the product of the protein concentration and molecular weight (MW), therefore we estimate the fraction of total molecules in parts per million (PPM) by $$PPM_i={SC_i\/MW_i}/∑↙{j=1}↖n {SC_j\/MW_j}$$ where MWi is the molecular weight and SCi is the number of spectral counts for protein i and the summation in the denominator is over all the proteins identified in the experiment for a given tissue and condition.

4.41E0Parts per MillionThe number of spectral counts (SC) is approximately proportional to the product of the protein concentration and molecular weight (MW), therefore we estimate the fraction of total molecules in parts per million (PPM) by $$PPM_i={SC_i\/MW_i}/∑↙{j=1}↖n {SC_j\/MW_j}$$ where MWi is the molecular weight and SCi is the number of spectral counts for protein i and the summation in the denominator is over all the proteins identified in the experiment for a given tissue and condition.

3.65E0Parts per MillionThe number of spectral counts (SC) is approximately proportional to the product of the protein concentration and molecular weight (MW), therefore we estimate the fraction of total molecules in parts per million (PPM) by $$PPM_i={SC_i\/MW_i}/∑↙{j=1}↖n {SC_j\/MW_j}$$ where MWi is the molecular weight and SCi is the number of spectral counts for protein i and the summation in the denominator is over all the proteins identified in the experiment for a given tissue and condition.

2.5E0Parts per MillionThe number of spectral counts (SC) is approximately proportional to the product of the protein concentration and molecular weight (MW), therefore we estimate the fraction of total molecules in parts per million (PPM) by $$PPM_i={SC_i\/MW_i}/∑↙{j=1}↖n {SC_j\/MW_j}$$ where MWi is the molecular weight and SCi is the number of spectral counts for protein i and the summation in the denominator is over all the proteins identified in the experiment for a given tissue and condition.

2.44E0Parts per MillionThe number of spectral counts (SC) is approximately proportional to the product of the protein concentration and molecular weight (MW), therefore we estimate the fraction of total molecules in parts per million (PPM) by $$PPM_i={SC_i\/MW_i}/∑↙{j=1}↖n {SC_j\/MW_j}$$ where MWi is the molecular weight and SCi is the number of spectral counts for protein i and the summation in the denominator is over all the proteins identified in the experiment for a given tissue and condition.

2.37E0Parts per MillionThe number of spectral counts (SC) is approximately proportional to the product of the protein concentration and molecular weight (MW), therefore we estimate the fraction of total molecules in parts per million (PPM) by $$PPM_i={SC_i\/MW_i}/∑↙{j=1}↖n {SC_j\/MW_j}$$ where MWi is the molecular weight and SCi is the number of spectral counts for protein i and the summation in the denominator is over all the proteins identified in the experiment for a given tissue and condition.

1.97E0Parts per MillionThe number of spectral counts (SC) is approximately proportional to the product of the protein concentration and molecular weight (MW), therefore we estimate the fraction of total molecules in parts per million (PPM) by $$PPM_i={SC_i\/MW_i}/∑↙{j=1}↖n {SC_j\/MW_j}$$ where MWi is the molecular weight and SCi is the number of spectral counts for protein i and the summation in the denominator is over all the proteins identified in the experiment for a given tissue and condition.

1.97E0Parts per MillionThe number of spectral counts (SC) is approximately proportional to the product of the protein concentration and molecular weight (MW), therefore we estimate the fraction of total molecules in parts per million (PPM) by $$PPM_i={SC_i\/MW_i}/∑↙{j=1}↖n {SC_j\/MW_j}$$ where MWi is the molecular weight and SCi is the number of spectral counts for protein i and the summation in the denominator is over all the proteins identified in the experiment for a given tissue and condition.

1.92E0Parts per MillionThe number of spectral counts (SC) is approximately proportional to the product of the protein concentration and molecular weight (MW), therefore we estimate the fraction of total molecules in parts per million (PPM) by $$PPM_i={SC_i\/MW_i}/∑↙{j=1}↖n {SC_j\/MW_j}$$ where MWi is the molecular weight and SCi is the number of spectral counts for protein i and the summation in the denominator is over all the proteins identified in the experiment for a given tissue and condition.

1.88E0Parts per MillionThe number of spectral counts (SC) is approximately proportional to the product of the protein concentration and molecular weight (MW), therefore we estimate the fraction of total molecules in parts per million (PPM) by $$PPM_i={SC_i\/MW_i}/∑↙{j=1}↖n {SC_j\/MW_j}$$ where MWi is the molecular weight and SCi is the number of spectral counts for protein i and the summation in the denominator is over all the proteins identified in the experiment for a given tissue and condition.

1.59E0Parts per MillionThe number of spectral counts (SC) is approximately proportional to the product of the protein concentration and molecular weight (MW), therefore we estimate the fraction of total molecules in parts per million (PPM) by $$PPM_i={SC_i\/MW_i}/∑↙{j=1}↖n {SC_j\/MW_j}$$ where MWi is the molecular weight and SCi is the number of spectral counts for protein i and the summation in the denominator is over all the proteins identified in the experiment for a given tissue and condition.

1.55E0Parts per MillionThe number of spectral counts (SC) is approximately proportional to the product of the protein concentration and molecular weight (MW), therefore we estimate the fraction of total molecules in parts per million (PPM) by $$PPM_i={SC_i\/MW_i}/∑↙{j=1}↖n {SC_j\/MW_j}$$ where MWi is the molecular weight and SCi is the number of spectral counts for protein i and the summation in the denominator is over all the proteins identified in the experiment for a given tissue and condition.

1.53E0Parts per MillionThe number of spectral counts (SC) is approximately proportional to the product of the protein concentration and molecular weight (MW), therefore we estimate the fraction of total molecules in parts per million (PPM) by $$PPM_i={SC_i\/MW_i}/∑↙{j=1}↖n {SC_j\/MW_j}$$ where MWi is the molecular weight and SCi is the number of spectral counts for protein i and the summation in the denominator is over all the proteins identified in the experiment for a given tissue and condition.

1.52E0Parts per MillionThe number of spectral counts (SC) is approximately proportional to the product of the protein concentration and molecular weight (MW), therefore we estimate the fraction of total molecules in parts per million (PPM) by $$PPM_i={SC_i\/MW_i}/∑↙{j=1}↖n {SC_j\/MW_j}$$ where MWi is the molecular weight and SCi is the number of spectral counts for protein i and the summation in the denominator is over all the proteins identified in the experiment for a given tissue and condition.

1.42E0Parts per MillionThe number of spectral counts (SC) is approximately proportional to the product of the protein concentration and molecular weight (MW), therefore we estimate the fraction of total molecules in parts per million (PPM) by $$PPM_i={SC_i\/MW_i}/∑↙{j=1}↖n {SC_j\/MW_j}$$ where MWi is the molecular weight and SCi is the number of spectral counts for protein i and the summation in the denominator is over all the proteins identified in the experiment for a given tissue and condition.

1.4E0Parts per MillionThe number of spectral counts (SC) is approximately proportional to the product of the protein concentration and molecular weight (MW), therefore we estimate the fraction of total molecules in parts per million (PPM) by $$PPM_i={SC_i\/MW_i}/∑↙{j=1}↖n {SC_j\/MW_j}$$ where MWi is the molecular weight and SCi is the number of spectral counts for protein i and the summation in the denominator is over all the proteins identified in the experiment for a given tissue and condition.

1.21E0Parts per MillionThe number of spectral counts (SC) is approximately proportional to the product of the protein concentration and molecular weight (MW), therefore we estimate the fraction of total molecules in parts per million (PPM) by $$PPM_i={SC_i\/MW_i}/∑↙{j=1}↖n {SC_j\/MW_j}$$ where MWi is the molecular weight and SCi is the number of spectral counts for protein i and the summation in the denominator is over all the proteins identified in the experiment for a given tissue and condition.

5.95E-1Parts per MillionThe number of spectral counts (SC) is approximately proportional to the product of the protein concentration and molecular weight (MW), therefore we estimate the fraction of total molecules in parts per million (PPM) by $$PPM_i={SC_i\/MW_i}/∑↙{j=1}↖n {SC_j\/MW_j}$$ where MWi is the molecular weight and SCi is the number of spectral counts for protein i and the summation in the denominator is over all the proteins identified in the experiment for a given tissue and condition.

4.16E-1Parts per MillionThe number of spectral counts (SC) is approximately proportional to the product of the protein concentration and molecular weight (MW), therefore we estimate the fraction of total molecules in parts per million (PPM) by $$PPM_i={SC_i\/MW_i}/∑↙{j=1}↖n {SC_j\/MW_j}$$ where MWi is the molecular weight and SCi is the number of spectral counts for protein i and the summation in the denominator is over all the proteins identified in the experiment for a given tissue and condition.